Ground Engaging Machine

ABSTRACT

A ground engaging tooth for a ground engaging machine is disclosed. The ground engaging tooth may comprise a non-ground-engaging end, a ground-engaging end, a body extending between the non-ground-engaging end, the ground-engaging end, a top surface, a bottom surface, a left surface and a right surface. Further, the ground engaging tooth may comprise a coupling side including a pocket configured to receive a retaining device. Moreover, the ground engaging tooth may comprise a wear side including an integral-wear-insert. The integral-wear-insert may longitudinally extend along the bottom surface towards the ground-engaging end and vertically extend towards the top surface at the ground-engaging end.

TECHNICAL FIELD

This disclosure generally relates to a ground engaging machine and, more particularly, to a ground engaging tooth for a ground engaging machine.

BACKGROUND

Ground engaging machines, such as hydraulic mining shovels, draglines, electric rope shovels, excavators, track-loaders, bulldozers, skid-steer loaders, backhoe loaders and wheel loaders, are used in a variety of industries including, but not limited to, construction, agriculture and mining. Generally speaking, these machines include a frame, a power source supported by a frame, one or more motive devices operatively associated with the power source configured to transfer energy of the power source to ground and a work implement. In many instances the work implement may be a bucket configured to hold and carry a material the ground engaging machine is working on.

The material the ground engaging machine is working on may come in a variety of levels of hardness, compactness and abrasiveness. For example, the ground engaging machine may work on relatively soft, non-compacted and slightly abrasive, loamy soil or loose sand. Alternatively, and near the other end of the spectrum, the ground engaging machine may be called to work on hard, compacted and highly abrasive, tar, sand or concrete. In any event, as the level of hardness, compactness and abrasiveness increases, the ground engaging machine may utilize a ground engaging tooth (“GET”) positioned along an engagement edge of the work implement to penetrate the material worked on, thereby increasing productivity and decreasing damage to the work implement.

Although GETs are known, there is still room for improvement. For example, U.S. Pat. No. 5,081,774 (“Kuwano”) discloses a composite excavating tooth. More specifically, Kuwano discloses a tooth having a wear-resistant material centrally placed between top and bottom surfaces of the tooth. While Kuwano is arguably an effective and durable design, it may suffer from premature wear since the wear-resistant material is placed between the top and bottom surfaces of the tooth, rather than on a ground engaging surface.

The present disclosure is directed to overcoming one or more problems set forth above and/or other problems associated with the prior art.

SUMMARY

In accordance with one aspect of the present disclosure, a ground engaging tooth for a ground engaging machine is disclosed. The ground engaging tooth may comprise a non-ground-engaging end, a ground-engaging end opposite the non-ground-engaging end and a body. The body may extend between the non-ground-engaging end, the ground engaging end, a top surface, a bottom surface, a left surface and a right surface. Further, the ground engaging tooth may comprise a longitudinal axis that may extend lengthwise through the body. Moreover, the ground engaging tooth may comprise a separation plane. The separation plane may extend through the body orthogonal to the longitudinal axis and may be positioned between the non-ground-engaging end and the ground engaging end. Additionally, the ground engaging tooth may include a coupling side that may extend between the non-ground engaging end, the separation plane, the top surface, the bottom surface, the left surface and the right surface and may include a pocket configured to receive a retaining device. Further, the ground engaging tooth may comprise a wear side that may extend between the ground-engaging end, the separation plane, the top surface, the bottom surface, the left surface and the right surface. The wear side may include an integral-wear-insert that may longitudinally extend along the bottom surface towards the ground-engaging end and vertically extends towards the top surface at the ground-engaging end.

In accordance with another aspect of the present disclosure, a bucket for a ground engaging machine is disclosed. The bucket may comprise a first member and the first member may include a through-bore about which the bucket may rotate. Further, the bucket may comprise a casing. The casing may extend away from the first member and end at a top edge, a left edge, a right edge and an engagement edge. The casing may be configured to carry a material being worked on. Moreover, the bucket may include a ground engaging tooth. The ground engaging tooth may be fixedly attached to the bucket along the engagement edge and may be configured to engage the material being worked on. The ground engaging tooth may include a wear side extending between a ground-engaging end, a separation plane, a top surface, a bottom surface, a left surface and a right surface. Further, the wear side may include an integral-wear-insert that may longitudinally extend along the bottom surface towards the ground-engaging end and may vertically extend towards the top surface at the ground-engaging end.

In accordance with another embodiment of the present disclosure, a ground engaging machine is disclosed. The ground engaging machine may include a frame, a power source supported by the frame and a motive device operatively associated with the power source configured to transfer energy of the power source to ground. Further, the ground engaging machine may include an arm having a first end and a second end opposite the first end, the first end may be rotatably associated with the frame. Moreover, the ground engaging machine may include a bucket operatively coupled to the second end and the bucket may include an engagement edge. Additionally, the ground engaging machine may include a ground engaging tooth fixedly attached to the bucket along the engagement edge. The ground engaging tooth may be configured to engage the material worked on. Moreover, the ground engaging tooth may include a wear side extending between a ground-engaging end, a separation plane, a top surface, a bottom surface, a left surface and a right surface and the wear side may include a cast-in-place-integral-wear-insert that longitudinally extends along the bottom surface towards the ground-engaging end and vertically extends towards the top surface at the ground-engaging end. The cast-in-place-integral-wear-insert may have a WearFactor between about 1.5 and about 2.5.

These and other aspects and features of the present disclosure will be more readily understood when read in conjunction with the accompanying drawings.

BRIEF DESCRIPTION

FIG. 1 is side perspective view of a ground engaging machine constructed in accordance with the present disclosure.

FIG. 2 is a side perspective view of a bucket that may be utilized with the ground engaging machine of FIG. 1 constructed in accordance with the present disclosure.

FIG. 3 is a side perspective view of one example of a ground engaging tooth that may be utilized with the bucket of FIG. 2 and ground engaging machine of FIG. 1 constructed in accordance with the present disclosure.

FIG. 4 is a cross-sectional view of the ground engaging tooth of FIG. 3 along line 3-3 of FIG. 3 constructed in accordance with the present disclosure.

FIG. 5 is a bottom elevation view of the tooth of FIG. 3 constructed in accordance with the present disclosure.

FIG. 6 is side perspective view of another example of a ground engaging tooth that may be utilized with the bucket of FIG. 2 and ground engaging machine of FIG. 1 constructed in accordance with the present disclosure.

FIG. 7 is a cross-sectional view of the ground engaging tooth of FIG. 6 along line 7-7 of FIG. 6 constructed in accordance with the present disclosure.

FIG. 8 is a bottom perspective view of the tooth of FIG. 6 constructed in accordance with the present disclosure.

FIG. 9 is a profile view of one example of a ground engaging tooth that may be utilized with the bucket of FIG. 2 and ground engaging machine of FIG. 1 constructed in accordance with the present disclosure after mining oil sand overburden for an extended time period.

FIG. 10 is a profile view of one example of a ground engaging tooth that may be utilized with the bucket of FIG. 2 and ground engaging machine of FIG. 1 that is not constructed in accordance with the present disclosure after mining oil sand overburden on the same ground engaging machine as the ground engaging tooth in FIG. 9 as well as for the same amount of time as the ground engaging tooth in FIG. 9.

DETAILED DESCRIPTION OF THE DISCLOSURE

Various aspects of the disclosure will now be described with reference to the drawings, wherein like reference numbers refer to like elements, unless specified otherwise. Referring now to the drawings and with specific reference to FIG. 1, a ground engaging machine constructed in accordance with the present disclosure is shown and generally referred to by the reference numeral 20. The ground engaging machine 20 may include a frame 22 and a power source 24 supported by the frame 22. The power source 24 may be provided in any number of different forms including, but not limited to, Otto and Diesel cycle internal combustion engines, electric motors, and the like. Further, the ground engaging machine may include a motive device 26 operatively associated with the power source 24 configured to transfer energy of the power source 24 to ground. While the motive device 26 depicted is an endless track associated with a track-type machine, the motive device 26 may take other forms, such as a wheel.

Further, the ground engaging machine 20 may include an arm 28. The arm 28 may include a first end 30 and a second end 32 opposite the first end 30. The first end 30 may be rotatably associated with the frame 22. Further, as pictured, the arm 28 may be articulated. Therefore, the arm 28 may comprise a full range of movement wherein the second end 32 of the arm 28 may extend fully away from the first end 30. Alternatively, the second end 32 of the arm 28 may comprise a full range of movement wherein the second end 32 of the arm 28 may move towards the frame 22 of the ground engaging machine 20 near to the first end 30 of the arm 28.

The ground engaging machine 20 may additionally include a bucket 34. The bucket 34 may be operatively coupled to the second end 32 of the arm 28. For example, while referring to FIGS. 1 and 2, it may be seen that bucket 34 may include a first member 36 having a through-bore 38 through which a pin may be used to attach the bucket 34 to the second end 32 of the arm 28. Further, as seen in FIG. 2, the through-bore 38 may define an axis-of-rotation 40 about which the bucket 34 may rotate. Moreover, the bucket may include a casing 42 extending away from the first member 36 and ending at a top edge 44, a left edge 46, a right edge 48 and an engagement edge 50. The casing 42 may be configured to carry a material be worked on by the ground engaging machine 20.

Further, the bucket 34 of the ground engaging machine 20 may include a ground engaging tooth 52. As shown in FIGS. 1 and 2, the ground engaging tooth 52 may be fixedly attached to the bucket 34 along the engagement edge 50. The ground engaging tooth 52 may be configured to engage a material to be worked on by the ground engaging machine 20. While the ground engaging machine 20 depicted in FIGS. 1 and 2 is a hydraulic mining shovel, the present disclosure is not limited only to hydraulic mining shovels. The present disclosure also finds application with other ground engaging machines 20 such as, but not limited to, draglines, electric rope shovels, excavators, track-loaders, bulldozers, skid-steer loaders, backhoe loaders, wheel loaders and the like.

Turning to FIG. 3, one example of the ground engaging tooth 52 that may be utilized with the bucket 34 of FIG. 2 and the ground engaging machine 20 of FIG. 1 is depicted in a perspective view. As shown there, the ground engaging tooth 52 may include a non-ground-engaging end 54 and a ground-engaging end 56 opposite the non-ground-engaging end 54. Further, the ground engaging tooth 52 may include a body 58 extending between the non-ground-engaging end 54, the ground-engaging end 56, a top surface 60, a bottom surface 62, a left surface 64 and a right surface 66. Further, this example of the ground engaging tooth 52 may include a longitudinal axis 68 extending lengthwise through the body 58.

Referring now to FIG. 4, a cross-sectional view along line 4-4 of FIG. 3 of this example of the ground engaging tooth 52 is depicted. As seen therein, the ground engaging tooth 52 may additionally include a separation plane 70 that extends through the body 58 orthogonal to the longitudinal axis 68 and this separation plane 70 may be positioned between the non-ground-engaging end 54 and the ground-engaging end 56. The separation plane 70 may define a plane that delineates a coupling side 72 of the ground engaging tooth 52 from a wear side 74 of the ground engaging tooth 52.

The coupling side 72 may extend between the non-ground-engaging end 54, the separation plane 70, the top surface 60, the bottom surface 62, the left surface 64 and the right surface 66. The coupling side 72 may include a pocket 76 that is configured to receive retaining device 78 (shown in phantom in FIG. 3) and the retaining device 78 may be configured to fixedly attach the ground engaging tooth 52 along the engagement edge 50 of the bucket 34.

Alternatively, the wear side 74 may be the side of the ground engaging tooth 52 configured to engage the material being worked on by the ground engaging machine 20. The wear side 74 may extend between the separation plane 70, the ground-engaging end 56, the top surface 60, the bottom surface 62, the left surface 64 and the right surface 66. The wear side 74 may include an integral-wear-insert 80 and the integral-wear-insert 80 may longitudinally extend along the bottom surface 62 of the wear side 74 towards the ground-engaging end 56. At the ground-engaging end 56, the integral-wear-insert 80 may vertically extend towards the top surface 60 of the wear side 74.

Turning to FIG. 5, a bottom elevation view of the ground engaging tooth 52 according to FIG. 3 is depicted. As seen therein, the integral-wear-insert 80 may extend between the left surface 64 and the right surface 66 at the ground-engaging end 56. Further, the integral-wear-insert 80 may extend between the left surface 64 and the right surface 66 moving towards the separation plane 70 along the bottom surface 62. Turning back to the cross-sectional view of FIG. 4, it is seen that the integral-wear-insert 80 may include a longitudinal thickness 82 at the ground-engaging end 56 and a vertical thickness 84 along the bottom surface 62. Further, the vertical thickness 84 of the integral-wear-insert 80 may increase as the integral-wear-insert 80 extends away from the ground-engaging end 56 and towards the separation plane 70.

Additionally, the integral-wear-insert 80 depicted in FIGS. 3-5 may comprise a first material 86 while the remaining body 58 may be a second material 88. For example, the integral-wear-insert 80 may be, but is not limited to, white iron, tungsten carbide or porous aluminum oxide infiltrated with white iron or tungsten carbide. Accordingly, the first material 86 may be selected from a group consisting of, but not limited to, white iron, tungsten carbide and aluminum oxide. On the other hand, the second material 88 comprising the remaining body 58 may be, for example, cast steel or other material. Accordingly, the first material 86 may comprise an abrasion resistance greater than the second material 88. Moreover, in one example of the ground engaging tooth 52 depicted in FIGS. 3-5, the integral-wear-insert comprises between about 5% by volume and about 15% by volume of the wear side 74.

Furthermore, the integral-wear-insert 80 may be a cast-in-place-integral-wear-insert 90. More particularly, the first material 86 in solid phase may be placed inside of mold formed in the shape of the ground engaging tooth 52. Moreover, the first material 86 in solid phase may be placed at the ground-engaging end 56 of the wear side 74 of the mold. Subsequently, liquid phase second material 88 may be poured into the mold where the heat of the liquid phase second material 88 may remelt or dissolve a limited amount of the solid phase first material 86, when the first material is white iron or tungsten carbide, forming a continuous cast-in-place-integral-wear-insert 90 that may longitudinally extend along the bottom surface 62 of the wear side 74 towards the ground-engaging end 56 and towards the top surface 60 of the wear side 74 at the ground-engaging end 56. Further, the cast-in-place-integral-wear-insert 90 may extend between the left surface 64 and the right surface 66 at the ground-engaging end 56 and between the left surface 64 and the right surface 66 moving towards the separation plane 70 along the bottom surface 62.

Turning to FIG. 6, another example of a ground engaging tooth 52 that may be utilized with the bucket 34 of FIG. 3 and the ground engaging machine 20 of FIG. 1 is depicted in a perspective view. As seen there, this ground engaging tooth 52 may also include a non-ground engaging end 54 and a ground-engaging end 56 opposite the non-ground-engaging end 54. Further, this ground engaging tooth 52 may include a body 58 extending between the non-ground-engaging end 54, the ground-engaging end 56, a top surface 60, a bottom surface 62, a left surface 64 and a right surface 66. Further, this example of the ground engaging tooth 52 may include a longitudinal axis 68 extending lengthwise through the body 58. However, as seen in this drawing, this ground engaging tooth 52 may include a first tooth 92 and a second tooth 94 disposed parallel to the first tooth 92 at the ground-engaging end 56.

Referring now to FIG. 7, a cross-sectional view along line 7-7 of FIG. 3 of this example of the ground engaging tooth 52 is depicted. As seen there, this ground engaging tooth 52 may additionally include a separation plane 70 that extends through the body 58 orthogonal to the longitudinal axis 68 and this separation plane 70 may be positioned between the non-ground-engaging end 54 and the ground-engaging end 56. The separation plane 70 may define a plane that delineates a coupling side 72 of the ground engaging tooth 52 from a wear side 74 of the ground engaging tooth 52.

The coupling side 72 of this example of the ground engaging tooth 52 may extend between the non-ground-engaging 54, the separation plane 70, the top surface 60, the bottom surface 62, the left surface 64 and the right surface 66. The coupling side 72 may also include a pocket 76 that is configured to receive retaining device 78 (shown in phantom in FIG. 3) and the retaining device 78 may be configured to fixedly attach the ground engaging tooth 52 along the engagement edge 50 of the bucket 34.

Referring now to FIGS. 6 and 7, the wear side 74 may be the side of the ground engaging tooth 52 configured to engage the material being worked on by the ground engaging machine 20. The wear side 74 of this example of the ground engaging tooth 52 may extend between the separation plane 70, the ground-engaging end 56, the top surface 60, the bottom surface 62, the left surface 64 and the right surface 66. The wear side 74 may include an integral-wear-insert 80 associated with the first tooth 92 and the integral-wear-insert 80 may longitudinally extend along the bottom surface 62 of the wear side 74 towards the ground-engaging end 56. At the ground-engaging end 56, the integral-wear-insert 80 may vertically extend towards the top surface 60 of the first tooth 92. Additionally, the wear side 74 of this ground engaging tooth may additionally include a second-integral-wear-insert 96 associated with the second tooth 94. Like the integral-wear-insert 80, the second-integral-wear-insert 96 may longitudinally extend along the bottom surface 62 of the wear side 74 towards the ground-engaging end 56. Further, at the ground-engaging end 56, the second-integral-wear-insert 96 may vertically extend towards the top surface 60 of the second tooth 94.

Turning to FIG. 8, a bottom perspective view of the ground engaging tooth 52 according to FIG. 6 is depicted. As seen therein, the integral-wear-insert 80 may extend between the left surface 64 and a first inner surface 98 at the ground-engaging end 56. Further, the integral-wear-insert 80 may extend between the left surface 64 and the right surface 66 moving towards the separation plane 70 along the bottom surface 62. Turning back to the cross-sectional view of FIG. 4, it is seen that the integral-wear-insert 80 may include a longitudinal thickness 82 at the ground-engaging end 56 and a vertical thickness 84 along the bottom surface 62. Further, the vertical thickness 84 of the integral-wear-insert 80 may increase as the integral-wear-insert 80 extends away from the ground-engaging end 56 and towards the separation plane 70.

Turning back to FIG. 8, it is seen that the second-integral-wear-insert 96 may extend between the right surface 66 and a second inner surface 100 at the ground-engaging end 56. Further, the second-integral-wear-insert 96 may extend between the left surface 64 and the right surface 66 moving towards the separation plane 70 along the bottom surface 62. Turning back to the cross-sectional view of FIG. 4, it is to be understood that the right half of this ground engaging tooth 52 mirrors the left-half depicted in the drawing. Accordingly, the second-integral-wear-insert 96 may also include a longitudinal thickness 82 at the ground-engaging end 56 and a vertical thickness 84 along the bottom surface 62. Further, as seen therein, the vertical thickness 84 of the second-integral-wear-insert 96 may increase as the second-integral-wear-insert 96 extends away from the ground-engaging end 56 and towards the separation plane 70.

Additionally, the integral-wear-insert 80 and second-integral-wear-insert 96 depicted in FIGS. 6-8 may comprise a first material 86 while the remaining body 58 may be a second material 88. For example, the integral-wear-insert 80 and the second-integral-wear-insert 96 may be, but is not limited to, white iron, tungsten carbide or porous aluminum oxide infiltrated with white iron or tungsten carbide. Accordingly, the first material 86 may be selected from a group consisting of, but is not limited to, white iron, tungsten carbide and aluminum oxide. On the other hand, the second material 88 comprising the remaining body 58 may be, for example, cast steel or other material. Accordingly, the first material 86 may comprise a abrasion resistance greater than the second material 88. Moreover, in one example of the ground engaging tooth 52 depicted in FIGS. 6-8, both of the integral-wear-insert 80 and the second-integral-wear-insert 96 combined comprise between about 5% by volume and about 15% by volume of the wear side 74.

Furthermore, the integral-wear-insert 80 and the second-integral-wear-insert 96 may be a cast-in-place-integral-wear-insert 90. More particularly, the first material 86 in solid phase may be placed inside of mold formed in the shape of the ground engaging tooth 52. Moreover, the first material 86 in solid phase may be placed at the ground-engaging end 56 of the wear side 74 of the mold. Subsequently, liquid phase second material 88 may be poured into the mold where the heat of the liquid phase second material 88 may remelt or dissolve a very limited amount of the solid phase first material 86, when the first material is white iron or tungsten carbide, forming a continuous cast-in-place-integral-wear-insert 90 that may longitudinally extend along the bottom surface 62 of the wear side 74 towards the ground-engaging end 56 and towards the top surface 60 of the wear side 74 at the ground-engaging end 56. Further, the cast-in-place-integral-wear-insert 90 may extend between the left surface 64 and the right surface 66 at the ground-engaging end 56 and between the left surface 64 and the right surface 66 moving towards the separation plane 70 along the bottom surface 62.

INDUSTRIAL APPLICABILITY

In general, the present disclosure may find use in many applications including, but not limited to, increasing wear life of a ground engaging tooth 52 used on a bucket 34 of a ground engaging machine 20 used in the construction, agricultural and mining industries. Ground engaging machines 20 with which this disclosure finds usefulness include, but are not limited to, hydraulic mining shovels, draglines, electric rope shovels, excavators, track-loaders, bulldozers, skid-steer loaders, backhoe loaders, wheel loaders and the like. While being useful to any of the machines and industries described above, this disclosure may find particular usefulness with ground engaging machines 20 having a bucket 34 with a ground engaging tooth 52 fixedly attached along the engagement edge 50 of the bucket 34. Further, this disclosure may find usefulness when the ground engaging tooth 52 is used in abrasive environments such as, but not limited to, mining coal, oil sands and other abrasive materials. More particularly, the present disclosure finds usefulness by extending the wear life and improving wear shape of a ground engaging tooth 52 utilized on a bucket 34 of a ground engaging machine 20 used to mine abrasive materials such as, but not limited to, coal, oil sands and other abrasive materials.

In general, the present disclosure may employ a ground engaging tooth 52 depicted in either FIG. 3-5 or 6-8 that includes an integral-wear-insert 80. The integral-wear-insert 80 may be positioned on the wear side 74 of the ground engaging tooth 52 and may be made of a first material 86 having abrasion resistance greater than the second material 88 from which the remaining body 58 of the ground engaging tooth 52 is constructed. Further, the integral-wear-insert 80 may longitudinally extend along the bottom surface 62 of the wear side 74 towards the ground-engaging end 56 of the ground engaging tooth 52. Further, the integral-wear-insert 80 may vertically extend towards the top surface 60 of the ground engaging tooth 52 at the ground-engaging end 56. Moreover, the integral-wear-insert 80 may include a vertical thickness 84, and the vertical thickness 84 may increase as the integral-wear-insert moves away from the ground-engaging end 56. This structure leads to a ground engaging tooth 52 having a Wear Factor of between about 1.5 and about 2.5, a level heretofore unseen with a ground engaging tooth 52 lacking the integral-wear-insert 80 as disclosed herein. More specifically, this structure leads to a ground engaging tooth 52 having a Wear Factor of at least 1.72, a level heretofore unseen with a ground engaging tooth 52 lacking the integral-wear-insert 80 disclosed herein.

The Wear Factor may be described by the formula:

W _(D) =W _(B) /W _(I)

Where:

-   -   W_(D)=the Wear Factor;     -   W_(B)=the average tip length loss in millimeters per hour of         machine operation of at least three brand new ground engaging         teeth that do not utilize the integral-wear-insert disclosed         herein after being used on the bucket of a ground engaging         machine to mine oil sand overburden for about 725 hours; and     -   W_(I)=the average tip length loss in millimeters per hour of         machine operation of at least three brand new ground engaging         teeth that do utilize the integral-wear-insert disclosed herein         while simultaneously being used on the same bucket of the same         ground engaging machine to mine the same oil sand overburden for         about 725 hours.

An example of data used to determine the Wear Factor is depicted in Table 1 below.

TABLE 1 PTA Integral-Wear- PTA Integral-Wear- PTA Integral-Wear- Tip Style Cladded Insert Cladded Insert Cladded Insert Bucket Position #1 #2 #3 #4 #5 #6 Hours of Machine 727 727 727 727 727 727 Operation Length of New Tip (mm) 480 495 480 495 480 495 Length of Tip at End of 316 412 288 378 303 385 Test (mm) Length Loss of Tip per 0.226 0.114 0.264 0.162 0.243 0.151 Hour of Operation (mm) Average PTA Cladded 0.245 Wear Factor = 1.72 Tip Length Loss Per Hour of Machine Operation (mm) Average Integral-Wear- 0.142 Insert Wear Tip Length Loss Per Hour of Machine Operation (mm)

In addition to the above, the integral-wear-insert leads to a ground engaging tooth 52 having a heretofore unseen Pitch Factor ranging between about −1.0 and −4.0. More specifically, this structure leads to a ground engaging tooth 52 having a −2.45 Pitch Factor, a level heretofore unseen with a ground engaging tooth 52 lacking the integral-wear-insert 80 disclosed herein.

The Pitch Factor may be described by the formula:

P _(D) =P _(B) /P _(I)

Where:

-   -   P_(D)=the Pitch Factor;     -   P_(B)=the average tip pitch of at least three brand new ground         engaging teeth that do not utilize the integral-wear-insert         disclosed herein after being used on the bucket of a ground         engaging machine to mine oil sand overburden for about 725         hours, wherein tip pitch is defined as the angle between the         plane of the centerline of the tooth pocket and the plane that         extends through the point where the centerline of the tooth         pocket meet and the point at the longest end of the tooth; and     -   P_(I)=the average tip pitch of at least three brand new ground         engaging teeth that do utilize the integral-wear-insert         disclosed herein while simultaneously being used on the same         bucket of the same ground engaging machine to mine the same oil         sand overburden for about 725 hours, wherein tip pitch is         defined as the angle between the plane of the centerline of the         tooth pocket and the plane that extends through the point where         the centerline of the tooth pocket meet and the point at the         longest end of the tooth.

An example of data used to determine the Pitch Factor is depicted in Table 2 below.

TABLE 2 PTA Integral-Wear- PTA Integral-Wear- PTA Integral-Wear- Tip Style Cladded Insert Cladded Insert Cladded Insert Bucket Position #1 #2 #3 #4 #5 #6 Hours of Machine 727 727 727 727 727 727 Operation Pitch of New Tip −9.00 −9.00 −9.00 −9.00 −9.00 −9.00 (Degrees) Pitch of Tip at End of 0.00 −13.00 0.00 −13.00 0.00 −12.00 Test (Degrees) Pitch Differential at End −9.000 4.000 −9.000 4.000 −9.000 3.000 of Test (Degrees) Average PTA Cladded −9.0000 Pitch Factor = −2.45 Pitch Differential at End of Test (Degrees) Average Integral-Wear- 3.6667 Insert Tip Pitch Differential at End of Test (Degrees)

Furthermore, the integral-wear-insert disclosed herein leads to a ground engaging tooth 52 having a heretofore unseen Sharpness Factor ranging between about 1.0 and 3.0. More specifically, this structure leads to a ground engaging tooth 52 having a Sharpness Factor of about 2.03, a level heretofore unseen with a ground engaging tooth 52 lacking the integral-wear-insert 80 disclosed herein.

The Sharpness Factor may be described by the formula:

S _(D) =S _(B) /S _(I)

Where:

-   -   S_(D)=the Sharpness Factor;     -   S_(B)=the average tip sharpness of at least three brand new         ground engaging teeth that do not utilize the         integral-wear-insert disclosed herein after being used on the         bucket of a ground engaging machine to mine oil sand overburden         for about 725 hours, wherein tip sharpness is defined as the         angle at the endpoint of the tip where the top surface         intersects with the bottom surface; and     -   S_(I)=the average tip sharpness of at least three brand new         ground engaging teeth that do utilize the integral-wear-insert         disclosed herein while simultaneously being used on the same         bucket of the same ground engaging machine to mine the same oil         sand overburden for about 725 hours, wherein tip sharpness is         defined as the angle at the endpoint of the tip where the top         surface intersects with the bottom surface.

An example of data used to determine the Sharpness Factor is depicted in Table 3 below.

TABLE 3 PTA Integral-Wear- PTA Integral-Wear- PTA Integral-Wear- Tip Style Cladded Insert Cladded Insert Cladded Insert Bucket Position #1 #2 #3 #4 #5 #6 Hours of Machine 727 727 727 727 727 727 Operation Sharpness of New Tip 35.00 35.00 35.00 35.00 35.00 35.00 (Degrees) Sharpness of Tip at End 79.00 55.00 80.00 58.00 78.00 57.00 of Test (Degrees) Sharpness Differential 44.000 20.000 45.000 23.000 43.000 22.000 at End of Test (Degrees) Average PTA Cladded 44.0000 Sharpness Factor = 2.03 Tip Sharpness Differential at End of Test (Degrees) Average Integral-Wear- 21.6667 Insert Tip Sharpness Differential at End of Test (Degrees)

FIG. 9 is a profile view of a ground engaging tooth utilizing the integral wear insert described herein after placement on a bucket of a ground engaging machine used to mine oil sand overburden for about 725 hours in order to complete the tests necessary to determine the Wear Factor, the Pitch Factor and the Sharpness Factor. On the other hand, FIG. 10 is a profile view of a prior art ground engaging tooth that does not utilize the integral wear insert described herein placed on the same bucket of the same ground engaging machine to mine the same oil sand overburden for about 725 hours in order to complete the tests necessary to determine the Wear Factor, the Pitch Factor and the Sharpness Factor.

As graphically represented in these figures, the ground engaging tooth of FIG. 9 in longer in length than ground engaging tooth of FIG. 10 thereby leading to the heretofore unseen Wear Factor. Furthermore, as graphically depicted therein, the ground engaging tooth in FIG. 9 has a downward pitch (a) after mining oil sand overburden for about 725 hours, while the ground engaging tooth in FIG. 10 lacks any pitch after mining oil sand overburden for about 725 hours thereby leading to the heretofore unseen Pitch Factor. In effect, the pitch (a) in FIG. 10 has gone to zero, opposite the starting downward pitch (a), and therefore is not depicted. Moreover, as graphically represented in these figures, the ground engaging tooth in FIG. 9 has a sharpness ((3) after mining oil sand overburden for about 725 hours that is smaller than the sharpness ((3) of the ground engaging tooth of FIG. 10 after mining oil sand overburden for about 725 hours leading to the heretofore unseen Sharpness Factor.

The above description is meant to be representative only, and thus modifications may be made to the embodiments described herein without departing from the scope of the disclosure. Thus, these modifications fall within the scope of present disclosure and are intended to fall within the appended claims. 

What is claimed is:
 1. A ground engaging tooth for a ground engaging machine, comprising: a non-ground-engaging end; a ground-engaging end opposite the non-ground-engaging end; a body, the body extending between the non-ground-engaging end, the ground engaging end, a top surface, a bottom surface, a left surface and a right surface; a longitudinal axis, the longitudinal axis extending lengthwise through the body; a separation plane, the separation plane extending through the body orthogonal to the longitudinal axis and being positioned between the non-ground-engaging end and the ground engaging end; a coupling side, the coupling side extending between the non-ground engaging end, the separation plane, the top surface, the bottom surface, the left surface and the right surface, the coupling side including a pocket configured to receive a retaining device; a wear side, the wear side extending between the ground-engaging end, the separation plane, the top surface, the bottom surface, the left surface and the right surface, the wear side including an integral-wear-insert, the integral-wear-insert longitudinally extends along the bottom surface towards the ground-engaging end and vertically extends towards the top surface at the ground-engaging end.
 2. The ground engaging tooth according to claim 1, wherein the integral-wear-insert horizontally extends between the left surface and the right surface at the ground-engaging end and wherein the integral-wear-insert further horizontally extends between the left surface and the right surface along the bottom surface.
 3. The ground engaging tooth according to claim 1, wherein the integral-wear-insert includes a longitudinal thickness at the ground-engaging end and a vertical thickness along the bottom surface.
 4. The ground engaging tooth according to claim 3, wherein the vertical thickness increases as the integral-wear-insert longitudinally extends away from the ground-engaging end towards the separation plane.
 5. The ground engaging tooth according to claim 1, wherein the integral-wear-insert is a cast-in-place-integral-wear-insert.
 6. The ground engaging tooth according to claim 1, wherein the integral-wear-insert comprises a first material and the remaining body comprises a second material.
 7. The ground engaging tooth according to claim 6, wherein the first material comprises a abrasion resistance greater than the second material.
 8. The ground engaging tooth according to claim 6, wherein the first material is selected from a group consisting of white iron, tungsten carbide and aluminum oxide.
 9. The ground engaging tooth according to claim 1, wherein the integral-wear-insert comprises between about 5% by volume and about 15% by volume of the wear side.
 10. A bucket for a ground engaging machine, comprising: a first member, the first member including a through-bore about which the bucket may rotate; a casing, the casing attached to and extending away from the first member and ending at a top edge, a left edge, a right edge and an engagement edge, the casing configured to carry a material being worked on; a ground engaging tooth, the ground engaging tooth fixedly attached to the bucket along the engagement edge configured to engage the material being worked on, the ground engaging tooth including a wear side extending between a ground-engaging end, a separation plane, a top surface, a bottom surface, a left surface and a right surface, the wear side including an integral-wear-insert that longitudinally extends along the bottom surface towards the ground-engaging end and vertically extends towards the top surface at the ground-engaging end.
 11. The bucket according to claim 10, wherein the integral-wear-insert horizontally extends between the left surface and the right surface at the ground-engaging end and further wherein the integral-wear-insert extends between the left surface and the right surface along the bottom surface.
 12. The bucket according to claim 10, wherein the integral-wear-insert includes a longitudinal thickness at the ground-engaging end and a vertical thickness along the bottom surface and further wherein the vertical thickness increases as the integral-wear-insert longitudinally extends away from the ground-engaging end towards the separation plane.
 13. The bucket according to claim 10, wherein the integral-wear-insert is a cast-in-place-integral-wear-insert.
 14. The bucket according to claim 13, wherein the cast-in-place-integral-wear-insert comprises a first material and the remaining wear side comprises a second material and further wherein the first material comprises a abrasion resistance greater than the second material.
 15. The bucket according to claim 10, wherein the integral-wear-insert comprises between about 5% by volume and 15% by volume of the wear side.
 16. A ground engaging machine, comprising: a frame; a power source supported by the frame; a motive device operatively associated with the power source configured to transfer energy of the power source to ground; an arm having a first end and a second end opposite the first end, the first end rotatably associated with the frame; a bucket, the bucket operatively coupled to the second end and including an engagement edge; a ground engaging tooth fixedly attached to the bucket along the engagement edge configured to engage a material worked on, the ground engaging tooth including a wear side extending between a ground-engaging end, a separation plane, a top surface, a bottom surface, a left surface and a right surface, the wear side including a cast-in-place-integral-wear-insert that longitudinally extends along the bottom surface towards the ground-engaging end and vertically extends towards the top surface at the ground-engaging end, wherein the ground engaging tooth with the cast-in-place-integral-wear-insert has a Wear Factor between about 1.5 and about 3.0.
 17. The ground engaging machine according to claim 16, wherein the cast-in-place-integral-wear-insert has a Pitch Factor about −1.0 and about −4.0.
 18. The ground engaging machine according to claim 16, wherein the cast-in-place-integral-wear-insert has a Sharpness Factor between about 1.0 and about 3.0.
 19. The ground engaging machine according to claim 16, wherein the cast-in-place-integral-wear-insert horizontally extends between the left surface and the right surface at the ground-engaging end, wherein the cast-in-place-integral-wear-insert extends between the left surface and the right surface along the bottom surface, wherein the cast-in-place-integral-wear-insert includes a longitudinal thickness at the ground-engaging end and a vertical thickness along the bottom surface, wherein the vertical thickness increases as the cast-in-place-integral-wear-insert longitudinally extends away from the ground-engaging end towards the separation plane, wherein the cast-in-place-integral-wear-insert comprises a first material and the remaining wear side comprises a second material and further wherein the first material comprises a abrasion resistance greater than the second material.
 20. The ground engaging machine according to claim 16, wherein the cast-in-place-integral-wear-insert comprises between about 5% by volume and 15% by volume of the wear side. 